Retentivity as an Indicator of the Capacity of Basins without an Outlet to Accumulate Water Surpluses

Major, Maciej; Cieśliński, Roman

doi:10.15244/pjoes/58650

Cited by 5 publications

(4 citation statements)

References 22 publications

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“…Until 2000, they ranged from 400 to 500 mm. After this time, an increase (Major and Cieśliński 2015) in rainfall to the level of 600-650 mm can be seen, and in recent years it has exceeded 700 mm. You can also find years with annual rainfall exceeding 900 mm (2017).…”

Section: Fall and Evaporationmentioning

confidence: 96%

Determination of retention value using Mike She model in the area of young glacial catchments

Cieśliński

2020

Appl Water Sci

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The aim of the paper is the identification of the kinds and conditions of retention occurring in the selected of young glacial catchment (the Potok Oliwski) in natural and anthropogenic conditions by means of the mathematic model of Mike She. As a result of the performed calculations it has been possible to determine that the studied area, thanks to the nature-shaped factors, has a high retention potential, which refers to the ground water storage. The conditions of surface retention, in which a great role is played by blind drainage, have been analysed as well.

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Section: Fall and Evaporationmentioning

confidence: 96%

Determination of retention value using Mike She model in the area of young glacial catchments

Cieśliński

2020

Appl Water Sci

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“…According to the Eqs. (10) and 11, we calculated the relative RCC of the economy in the TRB by determining the maximum and minimum values of C sg . Then we divided the carrying state based on the degrees of carrying state according to the classification criteria in Table 1.…”

Section: Relative Resources Carrying Capacity In Trb Taking Xinjiang mentioning

confidence: 99%

“…RCC is one of the most popular and noted branches of the carrying capacity. Research fields of RCC included but are not limited to water resources carrying capacity (WRCC) [8][9][10][11][12][13][14], land resources carrying capacity (LRCC) [15][16][17][18][19], grassland carrying capacity [20,21], ocean carrying capacity [22][23][24], environment carrying capacity [25][26][27][28], and ecological carrying capacity [29][30][31][32], etc. LRCC and WRCC were studied especially broadly and deeply at the global, national, and local scales.…”

Section: Introductionmentioning

confidence: 99%

An Improved Method for Evaluating Regional Resource Carrying Capacities: A Case Study of the Tarim River Basin in Arid China

Wang¹,

Wang²,

Ye³

et al. 2019

Pol. J. Environ. Stud.

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Resource endowment and resource carrying capacity (RCC) are the most important cornerstones of regional sustainable development. By applying a newly established RCC method, namely, the relative resources carrying capacity (RRCC) method, we evaluated the RCC in the Tarim River basin (TRB) in arid China in Xinjiang during 2000-2011. Research results show that the relative resources carrying capacity can be effectively served as indicators of regional resources sustainable development status. Taking Xinjiang as the reference region, the TRB can be characterized as an area with an overloaded population and surplus economy during the whole research period, where land resources are relative advantage resources carrying the regional population growth and economic development and water resources are relative disadvantage resources restricting rapid regional development. Taking TRB as the reference region, 42 counties and cities in TRB performed significant temporal and spatial disparities according to the RRCC based on population and economic perspectives. Based on the spatial-temporal evolution of RRCC, 42 counties and cities in TRB were classified into four matching modes (A, B, C, and D). The spatial-temporal evolution characteristics and mechanisms about the 42 prefectures and cities were examined, and the suitable development strategies for every different mode were recommended.

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“…For water management in hummocky areas, it is important to model water flow and hydrological processes which changed the amount of water stored in pond over time (Major, Cieśliński 2015). Numerous studies have investigated the hydrological processes which influenced the water budget of midfield and midforest ponds (Millar 1971 The objective of this paper was to evaluate the possibility of LiDAR (Light Detection And Ranging) data use for description of midfield ponds morphometry.…”

Section: Introductionmentioning

confidence: 99%

Model for the Volume-Area-Depth Relations of Midfield Ponds using LiDAR

Fiedler

Antkowiak

Oliskiewicz-Krzywicka

et al. 2017

J. Ecol. Eng.

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Small midfield ponds have important functions in the hydrology and ecology of hummocky areas of Poland. Because of their sensitivity to meteorological conditions, their number and hydroperiod are altered as a result of climate changes and agriculture pressure. Accurate estimation of the pond area and storage capacities requires upto-date high-resolution elevation data. In this paper, we developed 0.2 m and 1.0 m bare-earth DEMs from LiDAR data and compared them with DEMs obtained from old bathymetric maps. Then, we calculated A-h and V-h relations and compared them with the relations derived from simplified models describing the pond shape. The analyses showed that LiDAR data are also useful for detecting changes in the ponds morphometry.

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Retentivity as an Indicator of the Capacity of Basins without an Outlet to Accumulate Water Surpluses

Cited by 5 publications

References 22 publications

Determination of retention value using Mike She model in the area of young glacial catchments

Determination of retention value using Mike She model in the area of young glacial catchments

An Improved Method for Evaluating Regional Resource Carrying Capacities: A Case Study of the Tarim River Basin in Arid China

Model for the Volume-Area-Depth Relations of Midfield Ponds using LiDAR

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